DE3225716C1 - Process for flue gas desulphurisation - Google Patents

Abstract

In the process, the clean gas stream is heated prior to entry into a heat exchanger by a fraction of clean gases, which are withdrawn after the heat exchanger and are mixed with the clean gases prior to the heat exchanger.

Description

Claims: 1. Process for flue gas desulfurization using of gas scrubbing of any type with downstream regenerative or recuperative Heat exchanger, with hot gas added to the clean gas stream upstream of the heat exchanger is, characterized in that the hot gas from the reheated clean gas stream taken behind the heat exchanger and fed to the clean gas upstream of the heat exchanger will.

2. The method according to claim 1, characterized in that the required Amount of re-frozen hot gas depending on the temperature difference the temperature of the clean gas at the gas scrubber outlet and the temperature of the clean gas After admixing, the pure gas is fed via a controllable fan. The invention relates to a method for flue gas desulphurization using any gas scrubbing Design with downstream regenerative or recuperative heat exchanger, obei hot gas is added to the clean gas stream upstream of the heat exchanger.

A disadvantage of all wet processes is the fact that without additional Measures the washed clean gases in the saturated area. Condition and at low temperature Let the discharge out through the chimney.

In such a method, it is known (DE-AS 29 18526), a regenerative heat exchanger to use. which exchanges the washed clean gases against the incoming, hot raw gases are reheated to higher temperatures. The advantages are in it too see. that once the chimney elevation leads to a better distribution of the dismissed Releases gases into the atmosphere. on the other hand, this measure causes corrosion in the Chimney and the channels in front of it prevents this Carry out reheating without problems, as the droplets carried away from the Laundry only contain salts that are either thermal when heated decompose and any residues can therefore be easily cleaned off or - in the event of failure cleaning - can be easily removed by washing with water.

Gypsum processes in flue gas desulphurization have the disadvantage that the salts contained in the drops are extremely difficult to dissolve in water and therefore to form a permanent deposit on the heating surfaces of the heat exchanger to lead. which is not washable with water Also cleaning with the usual Methods (steam, air bubbles) fail here.

It has already been suggested to clean the wet gases before entering so much hot in the heat exchanger (i.e. between gas scrubbing and heat exchanger) To mix in raw gas that the water content of the drops before entering the heat exchanger evaporates. The one then dry gypsum dust should be cleaned from the heat exchanger surface The addition of raw gas affects the achievable degree of desulfurization. This is because. that the raw gas still has the full SOr content, which then corresponds accordingly the mixing ratio increases the SO2 content of the clean gas underlying the task. the drops carried away by the clean gases from the gas scrubbing process to eliminate without supplying external energy and without reducing the SOR content in to increase the clean gases This object is achieved in that the hot gas from taken from the reheated clean gas flow behind the heat exchanger and from the clean gas is fed in front of the heat exchanger. the required amount of recycled Hot gas depending on the temperature difference between the temperature of the Clean gas at the outlet of the gas scrubber and the temperature of the clean gas after dtr admixing The clean gas can be supplied via an adjustable fan.

Because the heated clean gas behind the heat exchanger has the same SOr content like the clean gas behind the laundry. in this way becomes any influencing the degree of desulfurization: s avoided.

Example In a power plant with a coal-fired boiler arise aB. 500000m3Xh exhaust gas with a temperature of 130 ° C. This exhaust gas is before entering the gas scrubbing in a heat exchanger, e.g. a regenerative heat exchanger. cooled to 75 C After passing through the gas scrubber, the steam-saturated flue gas, that leaves the laundry at about 45 ° C, the above-mentioned regenerative heat exchanger supplied To avoid deposits on the heating surfaces of the heat exchanger the water content of the droplets carried away by the laundry is determined by the admixture reduced by approx. 10-12% of the heated clean gas. This increases the clean gas temperature before entering the heat exchanger from approx.

45 ° C to approx. 50 ° C and finally in the heat exchanger to approx Heated to 100 ° C.

An exemplary embodiment of the invention is shown in the drawing and described in more detail below.

Claims (1)

The exhaust gases from an incinerator (1) including the device A dust separator designed as an electrostatic precipitator is first used to cool the flue gases (2) fed and then in a gas heat exchanger (4) in coordination with the cooled to the heat to be dissipated from the clean gas. The subsequent gas scrubbing (5) leaving pure gases is part of the before entering the gas heat exchanger (5) Heated clean gases returned via a controllable fan (7) for evaporation the water content of the droplets entrained from the gas scrubber (5) and thus for Avoidance of deposits on the heating surfaces of the heat exchanger (4). The recirculated clean gas volume is advanced by the desired temperature difference and determined after admixture